Systems and devices for infectious disease screening

ABSTRACT

A system ( 1 ) for infectious disease screening. The system is for use with an assay device ( 2 ) which incorporates an ultrasonic transducer for generating ultrasonic waves to lyse cells in a biological sample. The system ( 1 ) comprises a frequency control module which is configured to control the ultrasonic transducer ( 49 ) to oscillate at an optimum frequency for cell lysis, a PCR arrangement ( 16 ) which is configured to receive and amplify the DNA from the sample; and a detection arrangement ( 70 ) which is configured to detect the presence of an infectious disease in the amplified DNA and to provide an output which is indicative of whether or not the detection arrangement ( 70 ) detects the presence of an infectious disease in the amplified DNA.

FIELD

The present invention relates to systems and devices for infectiousdisease screening including, but not limited to, COVID-19 disease. Thepresent invention more particularly relates to systems and devices forscreening for viral infections using a Polymerase Chain Reaction (PCR)process including, but not limited to, the screening for SARS-CoV-2viral infections.

BACKGROUND

Technological advancements in the medical field have improved theefficiency of diagnostic methods and devices. Testing times have reduceddrastically, while ensuring reliable results. There are various testingmethods to test for infections of all types. To test for viralinfections, PCR (Polymerase Chain Reaction) is proven to be the mostreliable method. As with other methods, PCR has evolved to be moretime-efficient and cost-effective, while maintaining high standards ofreliability.

PCR is a technique that uses the two matching strands in DNA to amplifya targeted DNA sequence from just a few samples to billions of copies,which are then analysed using Gel Electrophoresis, which separates DNAsamples according to their size.

Conventional Polymerase Chain Reaction (PCR):

A complete conventional PCR test comprises 3 or 4 steps as describedbelow:

1. Cell Lysis and Nucleic Acid (DNA/RNA) Extraction:

Once a patient sample is collected, either from the nose (nasopharyngealswab) or the throat (oropharyngeal swab), the sample is mixed with theelution buffer. The eluted solution is then filtered to remove any largeparticles (hair, skin fragments etc.). The filtered solution is pouredinto a lysing chamber.

Cell lysis is then performed to break or rupture the lipid bilayer ofthe cells in the sample to provide a gateway through which cell'scomponents, including DNA/RNA, are extracted.

Cell lysis is performed either chemically or electromechanically, or acombination of both. The process extracts the components and thesolution is filtered to separate the nucleic acids (DNA/RNA) from othercell components. The DNA/RNA is then ready for the next step.

2. Reverse Transcription (RT):

This step is only required if the nucleic acid is RNA and not DNA. Theprocess involves introducing an enzyme, known as reverse transcriptase,to the PCR solution containing the RNA to create a complementary DNA(cDNA) sequence from the RNA at a temperature between 40-50° C. Thereverse transcription step would precede any PCR related action sincePCR requires DNA or cDNA.

3. Polymerase Chain Reaction (PCR)

The principle of PCR is same regardless of the type of DNA sample. PCRrequires five core ingredients to be processed: the DNA sample, primers,DNA nucleotide bases, a polymerase enzyme, and a buffer solution toensure appropriate conditions for the reaction.

The PCR involves a process of heating and cooling known as thermalcycling. The thermal cycling has three steps: Denaturation, Annealing,and Extension.

Denaturation starts with heating the reaction solution to 95° C.-100° C.The high temperature is required for separation of the double-strandedDNA or cDNA into single strands.

Annealing is the binding of primers to the denatured strands of sampleDNA or cDNA. This process requires a temperature of 55° C.-62° C. Oncethe temperature is reached, it initiates the annealing stage in whichthe primers attach to the single strands.

Once the primers are attached, the temperature is raised to around 72°C. for the polymerase to attach and extend the primers along the lengthof the single strand to make a new double-stranded DNA.

To achieve optimal results, the thermal cycle is repeated ˜20-40 times,depending on the number of base pairs required for the test, andensuring that the desired temperature is achieved at each stage.

4. Gel Electrophoresis

After PCR has been completed, a method known as electrophoresis can beused to check the quantity and size of the DNA fragments produced. DNAis negatively charged and, to separate it by size, the PCR-processedsample is placed in an agarose gel with a current running through thegel that pulls the negatively charged DNA to the opposite end. Largerpieces of DNA encounter more resistance in the solution and therefore donot move as far as smaller segments over the same period of time.

The distance the DNA fragments travel, when compared to a known sample,gives the result of the test. During solution preparation, before thegel electrophoresis step, a fluorescent dye is added in order to see thebands of DNA and based on their location the length of the DNA is known.

Rapid PCR:

Rapid PCR is performed using shorter thermal cycle times (20-60 secondsper cycle) than conventional PCR to reduce overall test times. Rapid PCRalso uses real-time PCR, an automated rapid thermocycling process thatincorporates amplification and detection in a single process inside aclosed reaction vessel. This process significantly reduces the risk ofcontamination. Rapid PCR uses Fluorescence spectroscopy for detectionsimultaneously with the PCR's thermal cycles.

Rapid RT-PCR incorporates another process in the overall test whentesting for viruses (RNA). The additional process is the ReverseTranscription used to create cDNA from the RNA prior to the PCR processas described above.

Fluorescence Spectroscopy:

Fluorescence spectroscopy is used as an alternative to GelElectrophoresis to reduce overall duration of the test. Fluorescencespectroscopy uses light to excite the electrons in molecules of certaincompounds and causes them to emit light. That light is detected by adetector for fluorescence measurement which can be used foridentification of molecule(s) or changes in the molecule.

A global virus outbreak of the SARS-CoV-2 virus (COVID-19 disease),classed as a pandemic has sky-rocketed the demand for virus test kits.The demand also requires tests to be performed more quickly thanconventional tests that typically take 4-8 hours to complete, or evenrapid tests that take more than 2 hours to give results.

Conventional virus testing methods are usually performed for largequantities of samples and processed simultaneously. However, the longduration for each step, majorly PCR, increases wait-time for results.The rapid-PCR technique provides some lead time over the conventionalPCR by reducing the thermal cycle time, shortening the overall test timeto around 1-2 hours. However, even this test time is too long for usefulmass rapid screening for infectious diseases, such as COVID-19.

There is a need for improved systems and devices for infectious diseasescreening which alleviate at least some of the problems outlined herein.

SUMMARY

According to some embodiments, there is provided a system for infectiousdisease screening, the system for use with an assay device whichincorporates an ultrasonic transducer for generating ultrasonic waves tolyse cells in a biological sample to release DNA, wherein the systemcomprises: a frequency control module which is configured to control theultrasonic transducer to oscillate at a plurality of frequencies withina predetermined sweep frequency range and to select a drive frequencyfor the ultrasonic transducer which is between a first predeterminedfrequency and a second predetermined frequency for lysing cells in thesample; a Polym erase Chain Reaction, “PCR”, arrangement which isconfigured to receive and amplify the DNA from the sample; and adetection arrangement which is configured to detect the presence of aninfectious disease in the amplified DNA and to provide an output whichis indicative of whether or not the detection arrangement detects thepresence of an infectious disease in the amplified DNA.

In some embodiments, the frequency control module is configured tocontrol the ultrasonic transducer to oscillate at a plurality offrequencies which track progressively across the predetermined sweepfrequency range.

In some embodiments, the system further comprises: an Analog-to-Digitalconverter which is configured to control the frequency of oscillation ofthe ultrasonic transducer, wherein the frequency control module isconfigured to monitor an Analog-to-Digital Conversion value of theAnalog-to-Digital converter as the frequency control module controls theultrasonic transducer to oscillate at the plurality of frequencieswithin the predetermined sweep frequency range.

In some embodiments, the frequency control module is configured todetect when the Analog-to-Digital Conversion value is above apredetermined threshold and to lock the drive frequency of theultrasonic transducer when the Analog-to-Digital Conversion value isabove the predetermined threshold.

In some embodiments, the frequency control module is configured tocontrol the ultrasonic transducer to oscillate at a plurality offrequencies within the predetermined sweep frequency range periodicallyduring the operation of the system.

In some embodiments, the system further comprises: a heating arrangementincorporating: a heating recess for receiving at least part of the PCRarrangement; a moveable support element; a first heating element whichis carried by the support element; a second heating element which iscarried by the support element at a spaced apart position from the firstheating element, wherein the support element is moveable between a firstposition in which the first heating element is positioned closer to theheating recess than the second heating element and a second position inwhich the second heating element is positioned closer to the heatingrecess than the first heating element; and a motor which is configuredto move the support element cyclically between the first position andthe second position.

In some embodiments, the heating arrangement comprises: a temperaturesensor which is configured to sense the temperature of a liquid withinthe PCR arrangement positioned within the heating recess, wherein thesystem is configured to control the movement of the first and secondheating elements in response to the sensed temperature.

In some embodiments, the system is configured to control the firstheating element to heat a liquid within the PCR arrangement tosubstantially 45° C. during a reverse transcriptase process.

In some embodiments, during a PCR process, the system is configured to:control the first heating element to heat a liquid within the PCRarrangement to substantially 55° C., control the second heating elementto heat a liquid within the PCR arrangement to substantially 95° C., andmove the support element cyclically between the first and secondpositions such that the first and second heating elements control thetemperature of a liquid within the PCR arrangement to cycle betweensubstantially 55° C. and substantially 95° C.

In some embodiments, the system further comprises: a fluorescencedetection arrangement which comprises at least one light source and atleast one photodetector, wherein the at least one light source isconfigured to transmit light at a predetermined wavelength into a liquidwithin the PCR arrangement and the photodetector is configured to detecta fluorescence in the liquid by detecting the intensity of light emittedfrom the liquid.

According to some embodiments, there is provided an assay device for usewith a system for infectious disease screening, the device comprising: asample chamber for receiving a biological sample to be screened; asonication chamber; an ultrasonic transducer which is carried by thedevice and configured to output ultrasonic waves to lyse cells withinthe sonication chamber; a Polymerase Chain Reaction, “PCR”, chamber; atransfer arrangement which comprises: a moveable flow path which ismoveable to selectively provide a fluid flow path between the samplechamber, the sonication chamber or the PCR chamber so that at least partof the sample can be transferred successively between the samplechamber, the sonication chamber and the PCR chamber.

In some embodiments, the transfer arrangement further comprises: atransfer chamber; and a piston element which is slideably receivedwithin the transfer chamber, the piston element being configured to movealong at least part of the length of the transfer chamber to generate: anegative pressure within the transfer chamber to draw fluid from thesample chamber or the sonication chamber into the transfer chamber, or apositive pressure within the transfer chamber to drive fluid from thetransfer chamber to the sonication chamber or the PCR chamber.

In some embodiments, the transfer arrangement is rotatably mounted tothe device and the transfer arrangement comprises a drive formationwhich is configured to engage a corresponding drive formation on part ofan assay system, such that rotation of the corresponding drive formationrotates the transfer arrangement to move the moveable flow path.

In some embodiments, the device further comprises: at least one furtherchamber, wherein the at least one further chamber stores a liquidsolution selected from a group consisting of an elution buffer, a lysingagent or a reagent.

In some embodiments, the device further comprises: a cover unit which ismoveably mounted to the device, the cover unit comprising a gaspermeable membrane, wherein the sample chamber comprises and open endwhich is closed by the cover unit when the cover unit is in a firstposition and open when the cover unit is moved to a second position topermit a sample to be introduced into the sample chamber.

In some embodiments, the transfer arrangement comprises a filtrationarrangement which is configured to filter fluid flowing out from themoveable flow path, the filtration arrangement comprising a first filterelement which is provided with pores of between 2 μm and 30 μm indiameter.

In some embodiments, the filtration arrangement comprises a secondfilter element which is superimposed on the first filter element, thesecond filter element being provided with pores of between 0.1 μm and 5μm in diameter.

In some embodiments, the filtration arrangement comprises a plurality ofbeads which are retained between the first filter element and the secondfilter element.

According to some embodiments, there is provided a system for infectiousdisease screening, the system comprising: an assay device for use with asystem for infectious disease screening, the assay device comprising: asample chamber for receiving a biological sample to be screened; asonication chamber; an ultrasonic transducer which is carried by thedevice and configured to output ultrasonic waves to lyse cells withinthe sonication chamber; a Polymerase Chain Reaction, “PCR”, chamber; atransfer arrangement which comprises: a moveable flow path which ismoveable to selectively provide a fluid flow path between the samplechamber, the sonication chamber or the PCR chamber so that at least partof the sample can be transferred successively between the samplechamber, the sonication chamber and the PCR chamber, wherein the systemfurther comprises: a frequency control module which is configured tocontrol the ultrasonic transducer to oscillate at a plurality offrequencies within a predetermined sweep frequency range and to select adrive frequency for the ultrasonic transducer which is between a firstpredetermined frequency and a second predetermined frequency for lysingcells in the sample; a Polymerase Chain Reaction, “PCR”, arrangementwhich is configured to receive and amplify the DNA from the sample; anda detection arrangement which is configured to detect the presence of aninfectious disease in the amplified DNA and to provide an output whichis indicative of whether or not the detection arrangement detects thepresence of an infectious disease in the amplified DNA. Where theinfectious disease is COVID-19, the detection arrangement is configuredto detect the presence of the SARS-CoV-2 virus that causes the COVID-19disease in the amplified DNA and to provide an output which isindicative of whether or not the detection arrangement detects thepresence of the COVID-19 disease in the amplified DNA.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the present invention may be more readily understood,embodiments of the present invention will now be described, by way ofexample, with reference to the accompanying drawings, in which:

FIG. 1 is a perspective schematic view of a system of some embodimentswith an assay device of some embodiments,

FIG. 2 is a schematic drawing of an assay device of some embodiments,

FIG. 3 is a schematic drawing of part of a system of some embodimentswith an assay device of some embodiments,

FIG. 4 is a perspective schematic view of part of an assay device ofsome embodiments,

FIG. 5 is a side view of the part of the assay device shown in FIG. 4,

FIG. 6 is an end view of the part of the assay device shown in FIG. 4,

FIG. 7 is a schematic drawing of part of an assay device of someembodiments,

FIG. 8 is a cross-sectional view of the part of the assay device shownin FIG. 7,

FIG. 9 is a cross-sectional view of the part of the assay device shownin FIG. 7,

FIG. 10 is a schematic diagram of the components of a filtrationarrangement of some embodiments,

FIG. 11 is a schematic drawing of part of an assay device of someembodiments,

FIG. 12 is schematic diagram showing a piezoelectric transducer modelledas an RLC circuit,

FIG. 13 is graph of frequency versus log impedance of an RLC circuit,

FIG. 14 is graph of frequency versus log impedance showing inductive andcapacitive regions of operation of a piezoelectric transducer,

FIG. 15 is flow diagram showing the operation of a frequency controlmodule of some embodiments,

FIG. 16 is a perspective view of part of an assay device of someembodiments,

FIG. 17 is a perspective view of part of an assay device of someembodiments,

FIG. 18 is a perspective view of part of an assay device of someembodiments,

FIG. 19 is a side view of the part of the assay device shown in FIG. 18,

FIG. 20 is an end view of the part of the assay device shown in FIG. 18,

FIG. 21 is a cross-sectional view of part of a system of someembodiments and part of an assay device of some embodiments,

FIG. 22 is a perspective view of part of a system of some embodimentsand part of an assay device of some embodiments,

FIG. 23 is a side view of part of an assay device of some embodiments,and

FIG. 24 is a perspective view of part of a system of some embodiments.

DETAILED DESCRIPTION

Aspects of the present disclosure are best understood from the followingdetailed description when read with the accompanying figures. It isnoted that, in accordance with the standard practice in the industry,various features are not drawn to scale. In fact, the dimensions of thevarious features may be arbitrarily increased or reduced for clarity ofdiscussion.

The following disclosure provides many different embodiments, orexamples, for implementing different features of the provided subjectmatter. Specific examples of components, concentrations, applicationsand arrangements are described below to simplify the present disclosure.These are, of course, merely examples and are not intended to belimiting. For example, the attachment of a first feature and a secondfeature in the description that follows may include embodiments in whichthe first feature and the second feature are attached in direct contact,and may also include embodiments in which additional features may bepositioned between the first feature and the second feature, such thatthe first feature and the second feature may not be in direct contact.In addition, the present disclosure may repeat reference numerals and/orletters in the various examples. This repetition is for the purpose ofsimplicity and clarity and does not in itself dictate a relationshipbetween the various embodiments and/or configurations discussed.

This disclosure establishes improved aspects of a rapid resultdiagnostic assay system designed for point of care (POC) and/or home usefor infectious disease screening, specifically SARS-COV-2 known to causeCOVID-19 disease.

The assay system of some embodiments comprises 13 main components: anassay device or pod containing various liquid chambers, a plungercolumn, a flow directing cog, a sonication chamber, a filtration array,a PCR fin, PCR reagents, a PCR method, a thermal cycler, a detectionapparatus, a lid, a method for reporting results, and a housing thatcontains all necessary parts to manipulate the pod.

Referring to FIG. 1 of the accompanying drawings, a system 1 forinfectious disease screening is configured for use with a removableassay device 2 which, in this embodiment, is in the form of a single-usepod. In some embodiments, the system 1 is provided separately from theassay device 2. In other embodiments, the system 1 is provided incombination with the assay device 2. In further embodiments, the assaydevice 2 is provided without the system 1 but for use with the system 1.

The system 1 comprises a housing 3 which houses the various componentsof the system 1. In this embodiment, the housing 3 comprises an opening4 which is closed by a door element 5. The door element 5 is configuredto move between an open position, as shown in FIG. 1 and a closedposition in which the door element 5 closes the opening 4 in the housing3. In this embodiment, the door element 5 is provided with a handle 6 tofacilitate opening and closing by a user. In this embodiment, the doorelement 5 is provided to enable a user to open the system 1 to insertthe assay device 2 into the system 1, as indicated generally by arrow 7in FIG. 1. Other embodiments incorporate a different access means topermit a user to insert the assay device 2 into the system 1.

In this embodiment, the system 1 is a portable system. The housing 3 iscompact to enable the system 1 to be carried easily and for the system 1to be positioned unobtrusively at a convenient location, such asadjacent an entrance door of a building. The portable configuration ofthe system 1 of some embodiments enables the system 1 to be carriedeasily to a location where there is a need for infectious diseasescreening. In some embodiments, the system 1 is configured to be poweredby a battery or another low power source of electricity so that thesystem 1 can be used at a remote location, without the need for mainselectricity. In other embodiments, the system 1 comprises a power sourceinput to be connected to mains electricity to power the system 1 and/orto charge a battery within the system 1.

The system 1 comprises a support platform 8 which is provided at thebase of the housing 3. The support platform 8 comprises a surface forcarrying the assay device 2. The support platform 8 comprises aplurality of guide members 9 which are located around the supportplatform 8 to guide the assay device 2 into a predetermined positionwhen the assay device 2 is inserted into the system 1. In thisembodiment, the support platform 8 is provided with a central aperture10 which is positioned beneath the assay device 2 when the assay device2 is carried by the support platform 8.

Referring now to FIG. 2 of the accompanying drawings, the assay device 2comprises a base unit 11 which, in this embodiment, comprises anenlarged lower end in order to provide stability to the assay device 2when the assay device 2 is resting on the base element 11. The assaydevice 2 further comprises an assay device housing 12 which houses theinternal components of the assay device 2, which are described in moredetail below. The assay device housing 12 comprises an upper end 13which is remote from the base element 11 and which is configured to beopened to provide access to within the assay device 2. A cover element14 is movably mounted to the assay device housing 12 to at least partlycover the upper end 13. The cover element 14 comprises a centralaperture 15. The cover element 14 will be described in more detailbelow.

The assay device 2 comprises a PCR arrangement 16 which protrudes fromone side of the assay device 2. The PCR arrangement 16 will be describedin more detail below.

Referring now to FIG. 3 of the accompanying drawings, when the assaydevice 2 is inserted into the system 1, the assay device 2 is guidedinto the predetermined position on the support platform 8 such that thePCR arrangement 16 is at least partly received within a heating recessof a heating arrangement 17, which is described in detail below.

The assay device 2 sits beneath a drive arrangement 18 which forms partof the system 1. In this embodiment, the drive arrangement 18 comprisesa drive element in the form of a plunger 19 which is configured to bemoved by the drive arrangement 18 outwardly from the drive arrangement18 so that a tip 20 of the plunger 19 moves through the aperture 15 inthe cover element 14 of the assay device 2 along the direction generallyindicated by arrow 21 to engage a piston element 22 within the assaydevice 2. The system 1 is configured to extend and retract the plungerelement 19 in order to move the piston element 22 during the operationof the system 1.

The system 1 comprises a control unit 23 which incorporates a computingdevice, such as a microprocessor, and a memory. The control unit 23 isconfigured to control the operation of the system 1 as described below.

Referring now to FIGS. 4-6 of the accompanying drawings, the assaydevice 2 comprises a body portion 24 which is elongate and which definesat least one internal chamber. In this embodiment, the body portion 24has sides which are defined by eight generally planar surfaces which arearranged such that the body portion 24 has an octagonal cross-section.It is, however, to be appreciated that other embodiments incorporate abody portion having a different shape and different cross-section.

In this embodiment, the body portion 24 defines a plurality of internalchambers. In this embodiment, the body portion 24 defines six internalchambers; a sample chamber 25, a wash chamber 26, a lysing agent chamber27, a liquid reagent chamber 28, a dry reagent chamber 29 and a wastechamber 30. The body portion 24 is also provided with a central aperture31.

The number of chambers within the assay device can vary in differentembodiments from 1 to as many as 10. In an embodiment for an SARS-CoV-2assay, the assay device 2 comprises six chambers.

One end of the body portion 24 is provided with a protrusion 32, asshown in FIG. 5. The protrusion 32 is provided with a plurality ofapertures 33, as shown in FIG. 6. Each aperture 33 provides a fluidcommunication path with a respective one of the chambers 25-30.

Referring now to FIG. 7 of the accompanying drawings, the assay device 2comprises a transfer arrangement 34 which is movably mounted to the bodyportion 24. The transfer arrangement 34 comprises a plunger column 35which defines an elongate transfer chamber 36. In this embodiment, theplunger column 35 is an elongate and generally cylindrical column whichis configured to be at least partly received within the central aperture31 of the assay device body 24.

The plunger column 35 is the central part of the assay device 2. It isalso how the liquid contained in the assay device 2 is moved andmanipulated to and from the various chambers as it goes through all thestages of preparation for PCR. The transfer chamber 36 contains a pistonelement 22 in the form of a rubber plunger tip that connects to aplunger 19 contained within the housing unit 3 of the system 1. Liquidis drawn into the transfer chamber 36 via negative pressure before beingforced out of the transfer chamber 36 towards its destination chambervia positive pressure.

The transfer arrangement 34 comprises an enlarged end 37. In thisembodiment, the enlarged end 37 is generally cylindrical and is providedwith a drive formation in the form of teeth 38 which are provided atspaced apart positions around the enlarged end 37. The teeth 38 areconfigured to engage a corresponding drive formation on the system 1such that rotation of the corresponding drive formation of the system 1rotates the transfer arrangement 34. The movement of the transferarrangement is controlled by a motor contained within the housing of thesystem 1. The motor is a brushless DC motor, a stepper motor or any sortof electronically driven motor unit.

Referring now to FIGS. 8 and 9 of the accompanying drawings, thetransfer arrangement 34 comprises a moveable flow path 39 which isdefined by internal passages within the enlarged end 37. The moveableflow path 39 is configured to move with the transfer arrangement 34relative to the assay device body 24. The transfer arrangement 34 isprovided with flow apertures 40, 41 which are fluidly coupled to themoveable flow path 39. The flow apertures 40, 41 are positioned suchthat the flow apertures 40, 41 are selectively aligned with theapertures 33 on the assay device body 24 in order to selectively fluidlycouple each respective chamber 25-30 to the moveable flow path 39depending on the position of the transfer arrangement 34 relative to theassay device body 24.

One of the flow apertures 40 is fluidly coupled with the transferchamber 36 to permit fluid to flow into or out from the transfer chamber36 when the piston element 22 is moved along at least part of the lengthof the transfer chamber 36 due to the positive or negative pressureproduced within the transfer chamber 36 as a result of the movement ofthe piston element 22.

The transfer arrangement 34 comprises a filtration arrangement 42 whichis provided within the enlarged end 37 such that fluid flowing along themoveable flow path 39 passes through the filtration arrangement 42. Inthis embodiment, the filtration arrangement 42 comprises an array offilters, gaskets and microbeads designed to separate larger pollutantsfrom the cells contained in the sample and trap the cells within a“lysing area”.

Referring to FIG. 10 of the accompanying drawings, the filtrationarrangement 42 comprises at least one filter element. In thisembodiment, the filtration arrangement 42 comprises a first filterelement 43 which is provided with pores of between 2 μm and 30 μm indiameter designed to filter out pollutants such as hair or dust. In thisembodiment, the filtration arrangement 42 comprises a second filterelement 44 which is superimposed on the first filter element 43. Thesecond filter element 44 is provided with pores of between 0.1 μm and 5μm in diameter where the pore size is selected to be slightly smallerthan the average size of the target cells so they are unable to passthrough the second filter element 44.

In this embodiment, the filtration arrangement 42 comprises gaskets45-47 which provide seals around the filter elements 43, 44. In thisembodiment, a larger gasket (approximately 200 μm thick) is providedbetween the first and second filter elements 43, 44 to create spacebetween the first and second filter for the lysing area.

In this embodiment, the filtration arrangement 42 comprises a pluralityof beads B which are retained between the first filter element 43 andthe second filter 44. In some embodiments, the beads B are microbeadshaving a diameter of approximately 100 microns. In some embodiments,approximately half of the beads B are buoyant so they collect near thetop of the filter arrangement 42 during sonication and the other halfare designed to not be buoyant and collect near the bottom of the filterarrangement 42. Between the two types of beads, a majority of the lysingarea will be filled with microbeads that help disrupt cell membranesduring sonication.

Referring now to FIG. 11 of the accompanying drawings, the transferarrangement 34 comprises a sonication chamber 48 which is positionedadjacent to the filtration arrangement 42 and which is fluidly coupledto the moveable flow path 39. In some embodiments, the sonicationchamber 48 has a volume of between 100 μl to 1000 μl. In someembodiments, the inlet to the sonication chamber 48 is positioned at alevel below the outlet of the sonication chamber 48, when the assaydevice 2 is standing upright, to allow liquid to flow from low to highand to let any air bubbles escape in the process.

The filtration arrangement 42 is provided within the sonication chamberand an ultrasonic transducer 49 is provided at the one end of thesonication chamber 48. In some embodiments, the filtration arrangement42 separates the inlet area of the sonication chamber 48 from the outletarea of the sonication chamber 48, substantially between on half or onequarter of the distance between the inlet and the outlet of thesonication chamber 48.

The ultrasonic transducer 49 is coupled electrically to the control unit23 of the system 1 when the assay device 2 is inserted into the system1. The ultrasonic transducer 49 is configured to be controlled by afrequency control module within the control unit 23 to oscillate at aselected frequency in order to lyse cell within the sonication chamber48 to release nucleic acid (DNA/RNA) from the cells.

The frequency control module is configured to control the ultrasonictransducer 49 to oscillate at a plurality of frequencies within apredetermined sweep frequency range and to select a drive frequency forthe ultrasonic transducer 49 which is between a first predeterminedfrequency and a second predetermined frequency for lysing cells withinthe sonication chamber 48.

In some embodiments, the frequency will be determined by the type ofcells that are being lysed as some cells may require differentfrequencies due to their physical characteristics (size, shape, presenceof cell wall, etc.).

There is an optimum frequency or frequency range for lysing cells withinthe sonication chamber. The optimum frequency or frequency range willdepend on at least the following four parameters:

1. Transducer Manufacturing Processes

In some embodiments, the ultrasonic transducer 49 comprises apiezoelectric ceramic. The piezoelectric ceramic is manufactured bymixing compounds to make a ceramic dough and this mixing process may notbe consistent throughout production. This inconsistency can give rise toa range of different resonant frequencies of the cured piezoelectricceramic.

If the resonant frequency of the piezoelectric ceramic does notcorrespond to the required frequency of operation, the process of lysingcells is not optimal. Even a slight offset in the resonant frequency ofthe piezoelectric ceramic is enough to impact the lysing process,meaning that the system will not function optimally.

2. Load on Transducer

During operation, any changes in the load on the ultrasonic transducer49 will inhibit the overall displacement of the oscillation of theultrasonic transducer 49. To achieve optimal displacement of theoscillation of the ultrasonic transducer 49, the drive frequency must beadjusted to enable the control unit 23 to provide adequate power formaximum displacement.

The types of loads that can affect the efficiency of the ultrasonictransducer 49 can include the amount of liquid on the transducer (i.e.the amount of liquid within the sonication chamber 48).

3. Temperature

Ultrasonic oscillations of the ultrasonic transducer 49 are partiallydamped by its assembly in the assay device 2. This dampening of theoscillations can cause a rise in local temperatures on and around theultrasonic transducer 49.

An increase in temperature affects the oscillation of the ultrasonictransducer 49 due to changes in the molecular behavior of the ultrasonictransducer 49. An increase in the temperature means more energy to themolecules of the ceramic, which temporarily affects its crystallinestructure. Although the effect is reversed as the temperature reduces, amodulation in supplied frequency is required to maintain optimaloscillation.

An increase in temperature also reduces the viscosity of the solutionwithin the sonication chamber 48, which may require an alteration to thedrive frequency to optimise lysis of cells within the sonication chamber48.

4. Distance to Power Source

The oscillation frequency of the ultrasonic transducer 49 can changedepending on the wire-lengths between the ultrasonic transducer 49 andthe oscillator-driver. The frequency of the electronic circuit isinversely proportional to the distance between the ultrasonic transducer49 and the control unit 23.

Although the distance parameter is primarily fixed in this embodiment,it can vary during the manufacturing process of the system 1. Therefore,it is desirable to modify the drive frequency of the ultrasonictransducer 49 to compensate for the variations and optimise theefficiency of the system.

An ultrasonic transducer 49 can be modelled as an RLC circuit in anelectronic circuit, as shown in FIG. 12. The four parameters describedabove may be modelled as alterations to the overall inductance,capacitance, and/or resistance of the RLC circuit, changing theresonance frequency range supplied to the transducer. As the frequencyof the circuit increases to around the resonance point of thetransducer, the log Impedance of the overall circuit dips to a minimumand then rises to a maximum before settling to a median range.

FIG. 13 shows a generic graph explaining the change in overall impedancewith increase in frequency in the RLC circuit. FIG. 14 shows how apiezoelectric transducer acts as a capacitor in a first capacitiveregion at frequencies below a first predetermined frequency f_(s) and ina second capacitive region at frequencies above a second predeterminedfrequency f_(p). The piezoelectric transducer acts as an inductor in aninductive region at frequencies between the first and secondpredetermined frequencies f_(s), f_(p). In order to maintain optimaloscillation of the transducer and hence maximum efficiency, the currentflowing through the transducer must be maintained at a frequency withinthe inductive region.

The frequency control module within the control unit 23 is configured tomaintain the frequency of oscillation of the ultrasonic transducer 49within the inductive region, in order to maximise the efficiency of thelysis of cells within the sonication chamber 48.

The frequency control module is configured to perform a sweep operationin which the frequency control module drives the transducer atfrequencies which track progressively across a predetermined sweepfrequency range. As the frequency control module performs the sweep, thefrequency control module monitors an Analog-to-Digital Conversion (ADC)value of an Analog-to-Digital converter which is provided within thecontrol unit 23 and coupled to the ultrasonic transducer 49. In someembodiments the ADC value is a parameter of the ADC which isproportional to the voltage across the ultrasonic transducer 49. Inother embodiments, the ADC value is a parameter of the ADC which isproportional to the current flowing through the ultrasonic transducer49.

During the sweep operation, the frequency control module locates theinductive region of the frequency for the transducer. Once the frequencycontrol module has identified the inductive region, the frequencycontrol module records the ADC value and locks the drive frequency ofthe transducer at a frequency within the inductive region (i.e. betweenthe first and second predetermined frequencies f_(s), f_(p)) in order tooptimise the operation of the ultrasonic transducer 49. When the drivefrequency is locked within the inductive region, the electro-mechanicalcoupling factor of the transducer is maximized, thereby maximizing theoperation of the ultrasonic transducer 49.

In some embodiments, the frequency control module is configured toperform the sweep operation to locate the inductive region each time theoscillation is started or re-started. In these embodiments, thefrequency control module is configured to lock the drive frequency at anew frequency within the inductive region each time the oscillation isstarted and thereby compensate for any changes in the parameters thataffect the efficiency of operation of the ultrasonic transducer 49.

In some embodiments, in order to ensure optimal operation of theultrasonic transducer 49, the frequency control module is configured tooperate in a recursive mode. When the frequency control module operatesin the recursive mode, the frequency control module runs the sweep offrequencies periodically during the operation of the system and monitorsthe ADC value to determine if the ADC value is above a predeterminedthreshold which is indicative of optimal oscillation of the operation ofthe ultrasonic transducer 49.

In some embodiments, the frequency control module runs the sweepoperation while the system is in the process of lysing cells in case thefrequency control module is able to identify a possible better frequencyfor the ultrasonic transducer 49. If the frequency control moduleidentifies a better frequency, the frequency control module locks thedrive frequency at the newly identified better frequency in order tomaintain optimal operation of the ultrasonic transducer 49.

FIG. 15 shows a flow diagram of the operation of the frequency controlmodule of some embodiments.

Referring now to FIGS. 16 and 17 of the accompanying drawings, the lidelement 14 of the assay device 2 comprises a generally planar coverelement 50 which is configured to close an open end of at least thesample chamber 25 of the assay device body 24. The lid element 14comprises side walls 51 which extend around the periphery of the covermember 50. In this embodiment, an air inlet aperture 52 is provided inone of the side walls 51.

In this embodiment, the lid element 14 comprises a pivotal mountingarrangement 53 for pivotally mounting the lid element 14 to the assaydevice body 24. In other embodiments, the lid element 14 is configuredwith a different movable mounting arrangement to moveably mount the lid14 to the assay device body 24.

The lid element 14 comprises a gas permeable membrane 54 which issuperimposed beneath the lid member 50 around the ends of the side walls51. The gas permeable membrane 54 provides a substantially gas tightseal around the side walls 51 and around the central aperture 15 toprevent cross contamination or accidental spillage. In some embodiments,the gas permeable membrane 54 is a Gore-Tex™ material.

In use, the air inlet aperture 52 allows air to flow into the lidelement 14 and for the air to flow through the gas permeable membrane 54and into at least the sample chamber 25 within the assay device body 24.

In other embodiments, the gas permeable membrane 54 may be replaced withanother one-way gas flow member, such as a valve.

Referring now to FIGS. 18-20 of the accompanying drawings, the PCRarrangement 16 of the assay device 2 comprises a fin element 55 which iscoupled to the assay device body 24 such that the fin element 55protrudes outwardly from the assay device body 24. The fin element 55comprises an enlarged mounting member 56 which is configured to beconnected to the assay device body 24. The mounting member 56 isprovided with a first aperture 57 and a second aperture 58 which extendthrough to the fin element 55 such that the apertures 57, 58 are influid communication with a PCR chamber 59 which is defined within thefin element 55. In this embodiment, the fin element 55 further comprisesa plurality of internal chambers 60 in a central portion 61 which partlysurrounds the PCR chamber 59.

The fin element 55 is generally rectangular with angled ends 62, 63which converge to a point 64. In use, after the sample passes throughboth the reagent chambers of the assay device 2, it is pushed into thePCR fin element 55 which contains the PCR chamber 59.

In some embodiments, the reagents selected for the PCR process arechosen in order to facilitate an extreme rRT-PCR process as well asallow for temperature monitoring via fluorescence. In some embodiments,the reagent formula consists of or comprises: 5 μM of each forward andreverse primer (6 total primers, 2 sets for detecting SARS-COV-2 and 1set to serve as a control for a successful PCR reaction), IX LCGreen+dye, 0.2 μM of each deoxynucleoside triphosphate (dNTP): dATP, dTTP,dGTP, dCTP, 50 mM Tris, 1.65 μM KlenTaq, 25 ng/μL BSA, 1.25 U/μL MaloneMurine leukemia virus reverse transcriptase (MMLV), 7.4 mM MgCl₂, andsulforhodamine B.

Referring now to FIGS. 21 and 22 of the accompanying drawings, the finelement 55 of the PCR arrangement 16 is configured to be at least partlyreceived within the heating arrangement 17.

In this embodiment, the heating arrangement 17 comprises two generallycircular planar discs 65, 66 which are spaced apart from one another androtatably mounted to a pivot member 67. A heating recess 68 is definedby a part of the space between the discs 65, 66.

In this embodiment, disc 65 is a movable support element which carries afirst heating element 69 a and a second heating element 69 b, as shownin FIG. 23. The first and second heating elements 69 a, 69 b are spacedapart from one another on either side of the disc 65.

The heating arrangement 17 further comprises a motor which is configuredto move the disc 65 to rotate about the pivot member 67 so that the disc65 moves between a first position in which the first heating element 69a is positioned closer to the heating recess 68 than the second heatingelement 69 b and a second position in which the second heating element69 b is positioned closer to the heating recess 68 than the firstheating element 69 a. The motor is coupled electrically to the controlunit 23 so that the control unit 23 can control the motor to move thedisc 65 cyclically between the first position and the second position.

In some embodiments, the heating arrangement 17 comprises a temperaturesensor which is configured to sense the temperature of a liquid withinthe PCR arrangement positioned within the heating recess 68 and thesystem is configured to control the movement of the first and secondheating elements in response to the sensed temperature.

Referring now to FIG. 24 of the accompanying drawings, the system 1comprises a fluorescence detection arrangement 70 which comprises agenerally planar support member 71 which is provided with an aperture 72through which the pivot member 67 extends. The fluorescence detectionarrangement comprises a first triangular portion 73 and a secondtriangular portion 74 and an indented portion 75. The planar body 71 andthe triangular portions 73, 74 are positioned in the space between thediscs 65, 66 of the heating arrangement.

The indented portion 75 is shaped to receive the pointed end of the finelement 55 of the PCR arrangement 16.

The detection arrangement 70 is provided with a plurality of lightemitters 76 along one edge of the recessed portion 75 and a plurality ofphoto receptors 77 along another edge of the recessed portion 75. Inthis embodiment, there are four light emitters in the form of four LEDswhich are each configured to transmit light at a different wavelengthand there are four photo detectors 77 which are each configured todetect light at a different wavelength. However, in other embodiments,there are a different number of light emitters and photo detectors.

The detection arrangement 70 is, in some embodiments, configured todetect the fluorescence emitted from the LCGreen+ and sulforhodamine Bdyes to monitor PCR, melting curves and temperature changes.

Result Reporting

In some embodiments, the system 1 comprises a display unit, such as anLCD monitor, on the exterior of the housing 3. After the informationfrom the system has been processed by the control unit 23, the result ofthe test will be displayed on the display unit. The four possibleresults of the assay are as follows: Positive, Negative, Inconclusive,or Invalid. In the case of a COVID-19 test, the criteria for the fourresults are shown in Table 1 below.

TABLE 1 SARS-COV-2 COVID COVID RNAse P Gene1 Gene2 ‘control’ ResultReport + + +/− 2019-nCOV Positive detected One of two is + +/−Inconclusive Inconclusive − − + 2019-nCOV not Negative detected − − −Invalid result Invalid

Example

The operation of a system of some embodiments will now be described fora SARS-COV-2 assay.

In the assay device 2, the first chamber is the sample chamber intowhich a user adds a target sample to be screened. In some embodiments,the target sample is between 1 ml to 5 ml in volume. The sample, afterbeing collected from the patient, is placed into an elution buffer priorto being added to the sample chamber. In some embodiments, the elutionbuffer comprises: 1M Imidazole solution, 1M Tris, 0.5M EDTA, Milli-Q orDeionized water.

The next chamber is the wash chamber. In some embodiments, the washchamber contains an excess amount (3 ml to 5 ml) of an elution buffer asmentioned above. The wash buffer is used to wash the sample to removeany potential contaminants.

The next chamber is the lysing agent chamber. In some embodiments, thelysing agent chamber contains a mixture of chemicals to assist in thecell lysing step of the assay. In some embodiments, the lysing agentcomprises a formulation, including, but not limited to the followingthree formulations:

Lysis Formula #1:

-   -   10 mM Tris    -   0.25% Igepal    -   CA-630    -   150 mM NaCl

Lysis Formula #2:

-   -   10 mM Tris-HCl    -   10 mM NaCl    -   10 mM EDTA    -   0.5% Triton-X100

Lysis Formula #3:

-   -   0.1 M LiCl    -   0.1M Tris-HCl    -   1% SDS    -   10 mm EDTA

The next chamber is the liquid reagent mixing chamber. Once the samplehas been sonicated and cell lysis has occurred, the freed nucleic acidis then pushed to the liquid reagent mixing chamber via pressure fromthe plunger column. The liquid reagent chamber contains theliquid-stable components of the rRT-PCR reagent mixture. Examplecomponents held in this chamber are, in some embodiments: Tris, IXLCGreen Dye, free nucleotides, MgCl₂ or sulforhodamine B.

The next chamber is the lyophilized reagent mixing chamber. This chambercontains a freeze-dried or lyophilized form of reagents that are notable to be stored for long periods in a liquid or hydrated state such asproteins. Example components that would be lyophilized for long-termstorage in the assay device are, in some embodiments: primers,polymerases, reverse transcriptase or bovine serum albumin (BSA).

The next chamber is the PCR chamber, this chamber is located external tothe main section of the pod in the PCR fin. This chamber is where thefinal mixed PCR solution (containing the freed nucleic acid from theinitial sample and all of the PCR reagents) is sent prior to the rRT-PCRprocess.

The final chamber is the waste chamber. This chamber holds all thediscarded components throughout the cycles of the assay device. Forexample, when the wash solution is pushed through the sonicationchamber, the solution is sent directly to the waste chamber upon exitingthe sonication chamber. The volume of this chamber should be at minimumthe total volume of all the liquid in the pod, plus the volume of thesample added.

PCR Methods

The method of some embodiments performs rRT-PCR for rapid detection andconfirmation of the presence of SARS-COV-2 in a sample. In order tocontrol the heating and cooling process necessary for a RT-PCR reactionto occur, the system of some embodiments uses the heating arrangement 17as a thermal cycler with dual heating elements that provide thenecessary temperature cycles.

The discs 65, 66 of the heating arrangement 17 rotate rapidly during theextreme rRT-PCR cycling to apply different heat levels to heat the PCRchamber to the desired temperatures. Heating elements 69 a, 69 b arelocated on opposite sides of the disc and each occupy an area of aquarter of the surface area of the disc. Each heating element 69 a, 69 bis programmed to reach a certain temperature.

The first heating element 69 a heats initially to 45° C., pauses for thereverse transcriptase step, then heats to its PCR temperature of 55° C.The second heating element 69 b heats to 95° C. and is only used duringthe PCR step. The other two sections of the disc 65 serve as insulatingareas between the heating elements 69 a, 69 b.

In some embodiment, the heat cycling occurs as follows: a ramp up to 45°C. of the first heating element 69 a while the PCR chamber is exposed toan insulating section of the disc. Once the first heating elementreaches 45° C., the disc 65 rotates to expose the PCR chamber to thesecond heating element 69 b for 2 seconds to allow the reversetranscriptase process to occur. Immediately following that, the firstheating element heats to 55° C. and the PCR process begins.

In some embodiments, the disc 65 begins to rapidly alternate betweenexposing the PCR chamber to the first and second heating elements forapproximately 30-35 cycles of heating and cooling. After each rotationof the disc 65, the temperature of the liquid in the PCR chamber ismonitored using passive fluorescence detection of the sulforhodamine Bdye.

When the second heating element 69 b is adjacent to the PCR chamber andthe temperature of the liquid within the PCR chamber reaches 95° C., thedisc 65 is triggered to rotate and move first heating element 69 aadjacent to the PCR chamber. When the temperature then drops to 55° C.,the disc 65 rotates back to the second heating element 69 b. Thiscompletes one cycle.

Following the last PCR cycle, the first heating element 69 a is rotatedadjacent to the PCR chamber and begins heating at a rate of 8° C./s to atemperature between 90° C. and 100° C. to allow for the melting analysisto be performed to confirm the presence of specific PCR products.

The system 1 is capable of providing test results within 10 minutes and,in some embodiments, as little as 5 minutes or less. This issignificantly faster than conventional PCR tests and it opens up thepossibility for rapid testing at homes, shops, entertainment venues, aswell as airports, bus and train terminals and other transportfacilities.

The system 1 of some embodiments is highly portable and can be carriedeasily to a location where testing is required. The efficient operationof the system enables the system of some embodiments to be powered by abattery, enabling the system to provide tests at virtually any location.

The foregoing outlines features of several embodiments so that those ofordinary skill in the art may better understand various aspects of thepresent disclosure. Those of ordinary skill in the art should appreciatethat they may readily use the present disclosure as a basis fordesigning or modifying other processes and structures for carrying outthe same purposes and/or achieving the same advantages of variousembodiments introduced herein. Those of ordinary skill in the art shouldalso realize that such equivalent constructions do not depart from thespirit and scope of the present disclosure, and that they may makevarious changes, substitutions, and alterations herein without departingfrom the spirit and scope of the present disclosure.

Although the subject matter has been described in language specific tostructural features or methodological acts, it is to be understood thatthe subject matter of the appended claims is not necessarily limited tothe specific features or acts described above. Rather, the specificfeatures and acts described above are disclosed as example forms ofimplementing at least some of the claims.

Various operations of embodiments are provided herein. The order inwhich some or all of the operations are described should not beconstrued to imply that these operations are necessarily orderdependent. Alternative ordering will be appreciated having the benefitof this description. Further, it will be understood that not alloperations are necessarily present in each embodiment provided herein.Also, it will be understood that not all operations are necessary insome embodiments.

Moreover, “exemplary” is used herein to mean serving as an example,instance, illustration, etc., and not necessarily as advantageous. Asused in this application, “or” is intended to mean an inclusive “or”rather than an exclusive “or”. In addition, “a” and “an” as used in thisapplication and the appended claims are generally be construed to mean“one or more” unless specified otherwise or clear from context to bedirected to a singular form. Also, at least one of A and B and/or thelike generally means A or B or both A and B. Furthermore, to the extentthat “includes”, “having”, “has”, “with”, or variants thereof are used,such terms are intended to be inclusive in a manner similar to the term“comprising”. Also, unless specified otherwise, “first,” “second,” orthe like are not intended to imply a temporal aspect, a spatial aspect,an ordering, etc. Rather, such terms are merely used as identifiers,names, etc. for features, elements, items, etc. For example, a firstelement and a second element generally correspond to element A andelement B or two different or two identical elements or the sameelement.

Also, although the disclosure has been shown and described with respectto one or more implementations, equivalent alterations and modificationswill occur to others of ordinary skill in the art based upon a readingand understanding of this specification and the annexed drawings. Thedisclosure comprises all such modifications and alterations and islimited only by the scope of the following claims. In particular regardto the various functions performed by the above described features(e.g., elements, resources, etc.), the terms used to describe suchfeatures are intended to correspond, unless otherwise indicated, to anyfeatures which performs the specified function of the described features(e.g., that is functionally equivalent), even though not structurallyequivalent to the disclosed structure. In addition, while a particularfeature of the disclosure may have been disclosed with respect to onlyone of several implementations, such feature may be combined with one ormore other features of the other implementations as may be desired andadvantageous for any given or particular application.

Embodiments of the subject matter and the functional operationsdescribed herein can be implemented in digital electronic circuitry, orin computer software, firmware, or hardware, including the structuresdisclosed in this specification and their structural equivalents, or incombinations of one or more of them.

The terms “computing device” and “data processing apparatus” encompassall apparatus, devices, and machines for processing data, including byway of example a programmable processor, a computer, or multipleprocessors or computers. The apparatus can include, in addition tohardware, code that creates an execution environment for the computerprogram in question, e.g., code that constitutes processor firmware, aprotocol stack, a database management system, an operating system, aruntime environment, or a combination of one or more of them. Inaddition, the apparatus can employ various different computing modelinfrastructures, such as web services, distributed computing and gridcomputing infrastructures.

The processes and logic flows described in this specification can beperformed by one or more programmable processors executing one or morecomputer programs to perform functions by operating on input data andgenerating output.

Processors suitable for the execution of a computer program include, byway of example, both general and special purpose microprocessors, andany one or more processors of any kind of digital computer. Generally, aprocessor will receive instructions and data from a read-only memory ora random access memory or both. The essential elements of a computer area processor for performing instructions and one or more memory devicesfor storing instructions and data. Generally, a computer will alsoinclude, or be operatively coupled to receive data from or transfer datato, or both, one or more mass storage devices for storing data, e.g.,magnetic, magneto-optical disks, or optical disks. However, a computerneed not have such devices. Devices suitable for storing computerprogram instructions and data include all forms of non-volatile memory,media and memory devices, including by way of example semiconductormemory devices, e.g., EPROM (Erasable Programmable Read-Only Memory),EEPROM (Electrically Erasable Programmable Read-Only Memory), and flashmemory devices; magnetic disks, e.g., internal hard disks or removabledisks; magneto-optical disks; and CD-ROM and DVD-ROM disks.

To provide for interaction with a user, some embodiments are implementedon a computer having a display device, e.g., a CRT (cathode ray tube) orLCD (liquid crystal display) monitor, for displaying information to theuser and a keyboard and a pointing device, e.g., a mouse or a trackball,by which the user can provide input to the computer. Other kinds ofdevices can be used to provide for interaction with a user as well; forexample, feedback provided to the user can be any form of sensoryfeedback, e.g., visual feedback, auditory feedback, or tactile feedback;and input from the user can be received in any form, including acoustic,speech, or tactile input.

In the present specification “comprise” means “includes or consists of”and “comprising” means “including or consisting of”.

The features disclosed in the foregoing description, or the followingclaims, or the accompanying drawings, expressed in their specific formsor in terms of a means for performing the disclosed function, or amethod or process for attaining the disclosed result, as appropriate,may, separately, or in any combination of such features, be utilised forrealising the invention in diverse forms thereof.

1. A COVID-19 disease screening system, the system comprising: aCOVID-19 assay device including a sonication chamber and a disc-shapedultrasonic transducer within the sonication chamber; a controllercomprising a processor configured to control at least one process of thesystem and a memory, the memory storing executable instructions which,when executed by the processor, cause the processor to provide an outputto perform the at least one process, the controller controlling theultrasonic transducer to oscillate at a plurality of frequencies withina predetermined sweep frequency range and to select a drive frequency atwhich the ultrasonic transducer acts as an inductor in an inductiveoperating region to achieve optimal displacement of the oscillation ofthe ultrasonic transducer for maximum oscillation displacement, thedrive frequency being between a first predetermined frequency belowwhich the ultrasonic transducer acts as a capacitor and a secondpredetermined frequency above which the ultrasonic transducer acts as acapacitor, wherein during operation of the system the controller:controls the ultrasonic transducer to oscillate and generate ultrasonicwaves in the sweep drive frequency range to lyse cells obtained from abiological sample suspended in a liquid medium placed in the sonicationchamber, wherein the generated ultrasound waves applied to the cellsagitate and disrupt the cellular membranes of the cells to releasenucleic acid (DNA or RNA) from the cells of the biological sample;identifies the inductive operating region and controls the ultrasonictransducer to oscillate at one or more frequencies within the inductiveoperating region in response to a load on the transducer from the liquidmedium inside the sonication chamber, determines, in response to a loadon the transducer from the liquid medium inside the sonication chamber,whether the drive frequency maintains the operation of the ultrasonictransducer in the inductive operating region at maximum oscillationdisplacement of the ultrasonic transducer, runs the sweep operationwhile the system is in the process of lysing the cells to identify apossible better frequency to maintain optimal displacement of theultrasonic transducer, and determines whether a new drive frequencywithin the inductive operating region is selected for the ultrasonictransducer to maintain the optimal displacement of the ultrasonictransducer for the maximum oscillation displacement in the inductiveoperating region in response to a load on the transducer from the liquidmedium inside the sonication chamber; an Analog-to-Digital converterwhich is configured to control the frequency of oscillation of theultrasonic transducer, wherein the memory of the controller storesexecutable instructions which, when executed by the processor, cause theprocessor to monitor a parameter of the Analog-to-Digital converterwhich is proportional to a current flowing through the ultrasoundtransducer as the controller controls the ultrasonic transducer tooscillate at the plurality of frequencies within the predetermined sweepfrequency range, the memory of the controller stores executableinstructions which, when executed by the processor, cause the processorto detect when the Analog-to-Digital Conversion value is above apredetermined threshold and to lock the drive frequency of theultrasonic transducer when the Analog-to-Digital Conversion value isabove the predetermined threshold; a Polymerase Chain Reaction, “PCR”,device which is configured to receive and amplify DNA from thebiological sample, the PCR device including a PCR chamber for receivingthe DNA; a heating device to apply different heat levels to heat the DNAin the PCR chamber to selected temperatures; and a detection devicewhich is configured to detect the presence of the SARS-CoV-2 virus thatcauses COVID-19 disease in the amplified DNA and to provide an outputwhich is indicative of whether or not the detection device detects thepresence of the COVID-19 disease in the amplified DNA.
 2. The COVID-19disease screening system of claim 1, wherein the controller performs asweep operation of the predetermined sweep frequency range to locate theinductive operating region and locks the drive frequency at the newfrequency within the inductive operating region. 3-4. (canceled)
 5. TheCOVID-19 disease screening system of claim 2, wherein the controllerperforms the sweep operation periodically during the operation of thesystem.
 6. The COVID-19 disease screening system of claim 1, wherein theheating device further comprises: a first and a second spaced apartrotatable circular planar discs; a heating recess between the first andsecond spaced apart discs for receiving at least part of the PCR deviceincluding the PCR chamber; a first heating element which is carried bythe first spaced apart disc; a second heating element which is carriedby the second spaced apart disc at a spaced apart position from thefirst heating element, wherein the first and second spaced apart discsare moveable between a first position in which the first heating elementis positioned closer to the heating recess than the second heatingelement and a second position in which the second heating element ispositioned closer to the heating recess than the first heating element;and a motor which is configured to move the first and second spacedapart discs relative to each other cyclically between the first positionand the second position to apply different heat levels to heat the PCRchamber to the selected temperatures.
 7. The COVID-19 disease screeningsystem of claim 6, wherein the heating device comprises: a temperaturesensor which is configured to sense the temperature of a liquid withinthe PCR device positioned within the heating recess, wherein the systemis configured to control the movement of the first and second heatingelements in response to the sensed temperature.
 8. The COVID-19 diseasescreening system of claim 6, wherein the memory of the controller storesexecutable instructions which, when executed by the processor, cause theprocessor to control the first heating element to heat a liquid withinthe PCR device to substantially 45° C. during a reverse transcriptaseprocess.
 9. The COVID-19 disease screening system of claim 7, wherein,during a PCR process, the memory of the controller stores executableinstructions which, when executed by the processor, cause the processorto: control the first heating element to heat a liquid within the PCRdevice to substantially 55° C., control the second heating element toheat a liquid within the PCR device to substantially 95° C., and movethe first and second spaced apart discs cyclically between the first andsecond positions such that the first and second heating elements controlthe temperature of a liquid within the PCR device to cycle betweensubstantially 55° C. and substantially 95° C.
 10. The COVID-19 diseasescreening system of claim 1, wherein the detection device comprises: afluorescence detection device which comprises at least one light sourceand at least one photodetector, wherein the at least one light source isconfigured to transmit light at a predetermined wavelength into a liquidwithin the PCR device and the photodetector is configured to detect afluorescence in the liquid by detecting the intensity of light emittedfrom the liquid. 11-18. (canceled)
 19. A COVID-19 disease screeningsystem comprising: a COVID-19 assay device comprising: a sample chamberfor receiving a biological sample to be screened for COVID-19 disease; asonication chamber; an ultrasonic transducer which is carried by thedevice in communication with the sonication chamber and configured tooutput ultrasonic waves to lyse cells within the sonication chamber, theultrasonic transducer being disc-shaped; a Polymerase Chain Reaction,“PCR”, chamber; and a transfer arrangement which comprises: a moveableflow path which is moveable to selectively provide a fluid flow pathbetween the sample chamber, the sonication chamber or the PCR chamber sothat at least part of the sample can be transferred successively betweenthe sample chamber, the sonication chamber and the PCR chamber; acontroller comprising a processor configured to control at least oneprocess of the system and a memory, the memory storing executableinstructions which, when executed by the processor, cause the processorto provide an output to perform the at least one process, the controllercontrolling the ultrasonic transducer to oscillate at a plurality offrequencies within a predetermined sweep frequency range and to select adrive frequency at which the ultrasonic transducer acts as an inductorin an inductive operating region to achieve optimal displacement of theoscillation of the ultrasonic transducer for maximum oscillationdisplacement, the drive frequency being between a first predeterminedfrequency below which the ultrasonic transducer acts as a capacitor anda second predetermined frequency above which the ultrasonic transduceracts as a capacitor, wherein during operation of the system thecontroller: controls the ultrasonic transducer to oscillate and generateultrasonic waves in the sweep frequency range to lyse cells obtainedfrom a biological sample suspended in a liquid medium placed in thesonication chamber, wherein the generated ultrasound waves applied tothe cells agitate and disrupt the cellular membranes of the cells torelease nucleic acid (DNA or RNA) from the cells of the biologicalsample; identifies the inductive operating region and controls theultrasonic transducer to oscillate at one or more frequencies within theinductive operating region in response to a load on the transducer fromthe liquid medium inside the sonication chamber, runs the sweepoperation while the system is in the process of lysing the cells toidentify a possible better frequency to maintain optimal displacement ofthe ultrasonic transducer, determines, in response to a load on thetransducer from the liquid medium inside the sonication chamber, whetherthe drive frequency maintains the operation of the ultrasonic transducerin the inductive operating region at maximum oscillation displacement ofthe ultrasonic transducer, and determines whether a new drive frequencywithin the inductive operating region is selected for the ultrasonictransducer to maintain the optimal displacement of the oscillation ofthe ultrasonic transducer for the maximum oscillation displacement inthe inductive operating region in response to a load on the transducerfrom the liquid medium inside the sonication chamber; anAnalog-to-Digital converter which is configured to control the frequencyof oscillation of the ultrasonic transducer, wherein the memory of thecontroller stores executable instructions which, when executed by theprocessor, cause the processor to monitor a parameter of theAnalog-to-Digital converter which is proportional to a current flowingthrough the ultrasonic transducer as the controller controls theultrasonic transducer to oscillate at the plurality of frequencieswithin the predetermined sweep frequency range, the memory of thecontroller stores executable instructions which, when executed by theprocessor, cause the processor to detect when the parameter of theAnalog-to-Digital converter is above a predetermined threshold and tolock the drive frequency of the ultrasonic transducer when the parameterof the Analog-to-Digital converter is above the predetermined threshold;a Polymerase Chain Reaction, “PCR”, device which is configured toreceive and amplify DNA from the biological sample, the PCR deviceincluding the PCR chamber for receiving the DNA; a heating device toapply different heat levels to heat the DNA in the PCR chamber toselected temperatures; and a detection device which is configured todetect the presence of the SARS-CoV-2 virus that causes COVID-19 diseasein the amplified DNA and to provide an output which is indicative ofwhether or not the detection device detects the presence of the COVID-19disease in the amplified DNA.
 20. The COVID-19 disease screening systemof claim 19, wherein the detection device further comprises afluorescence detection arrangement which comprises at least one lightsource and at least one photodetector, wherein the at least one lightsource is configured to transmit light at a predetermined wavelengthinto a liquid within the PCR arrangement and the photodetector isconfigured to detect a fluorescence in the liquid by detecting theintensity of light emitted from the liquid.
 21. A COVID-19 diseasescreening system, the system comprising: a COVID-19 assay deviceincluding a sonication chamber and a disc-shaped ultrasonic transducerfor generating ultrasonic waves; a frequency controller comprising aprocessor and a memory, the memory storing executable instructionswhich, when executed by the processor, cause the processor to provide anoutput to perform the at least one process, the frequency controllercontrolling the ultrasonic transducer to oscillate at a plurality offrequencies within a predetermined sweep frequency range and to select adrive frequency at which the ultrasonic transducer acts as an inductorin an inductive operating region to achieve optimal displacement of theoscillation of the ultrasonic transducer at maximum oscillationdisplacement, the drive frequency being between a first predeterminedfrequency below which the ultrasonic transducer acts as a capacitor anda second predetermined frequency above which the ultrasonic transduceracts as a capacitor, wherein during operation of the system thefrequency controller: controls the ultrasonic transducer to oscillateand generate ultrasonic waves in the sweep frequency range to lyse cellsobtained from a biological sample suspended in a liquid medium placed inthe sonication chamber, wherein the generated ultrasound waves appliedto the cells agitate and disrupt the cellular membranes of the cells torelease nucleic acid (DNA or RNA) from the cells of the biologicalsample; identifies the inductive operating region and controls theultrasonic transducer to oscillate at one or more frequencies within theinductive operating region in response to a load on the transducer fromthe liquid medium inside the sonication chamber, determines, in responseto a load on the transducer from the liquid medium inside the sonicationchamber whether the drive frequency maintains the operation of theultrasonic transducer in the inductive operating region at maximumoscillation displacement of the ultrasonic transducer, runs the sweepoperation while the system is in the process of lysing the cells toidentify a possible better frequency to maintain optimal displacement ofthe ultrasonic transducer, and determines whether a new drive frequencywithin the inductive operating region is selected for the ultrasonictransducer to maintain the optimal displacement of the oscillation ofthe ultrasonic transducer for the maximum oscillation displacement inthe inductive operating region in response to a load on the transducerfrom the liquid medium inside the sonication chamber; anAnalog-to-Digital converter which is configured to control the frequencyof oscillation of the ultrasonic transducer, wherein the memory of thecontroller stores executable instructions which, when executed by theprocessor, cause the processor to monitor a parameter of theAnalog-to-Digital converter which is proportional to a current flowingthrough the ultrasound transducer as the controller controls theultrasonic transducer to oscillate at the plurality of frequencieswithin the predetermined sweep frequency range, the memory of thecontroller stores executable instructions which when executed by theprocessor, cause the processor to detect when the Analog-to-DigitalConversion value is above a predetermined threshold and to lock thedrive frequency of the ultrasonic transducer when the Analog-to-DigitalConversion value is above the predetermined threshold; a PolymeraseChain Reaction, “PCR”, device which is configured to receive and amplifyDNA from the biological sample in a liquid within the PCR device, thePCR device including a PCR chamber for receiving the DNA; a heatingdevice to apply different heat levels to heat the DNA in the PCR chamberto selected temperatures; and a fluorescence detection device to detectthe presence of the SARS-CoV-2 virus that causes COVID-19, thefluorescence detection device comprises: at least one light source; andat least one photodetector, wherein the at least one light source isconfigured to transmit light at a predetermined wavelength into theliquid within the PCR device and the photodetector is configured todetect the intensity of light emitted from the liquid to detect afluorescence in the liquid which indicates the presence of theSARS-CoV-2 virus that causes COVID-19 disease in the amplified DNA,wherein the fluorescence detection device provides an output which isindicative of whether or not the fluorescence detection device detectsthe presence of the COVID-19 disease in the amplified DNA.
 22. TheCOVID-19 disease screening system of claim 19, wherein the controllerperforms a sweep operation to locate the inductive operating region andlocks the drive frequency at a new frequency within the inductiveoperating region.
 23. The COVID-19 disease screening system of claim 22,wherein the controller performs the sweep operation periodically duringthe operation of the system. 24-25. (canceled)
 26. The COVID-19 diseasescreening system of cairn 21, wherein the frequency controller performsa sweep operation to locate the inductive operating region and locks thedrive frequency at a new frequency within the inductive operatingregion.
 27. The COVID-19 disease screening system of claim 26, whereinthe frequency controller performs the sweep operation periodicallyduring the operation of the system.
 28. (canceled)